Probing Gravity in Near Earth Orbits with LAGEOS and LARES
Caterina Lops (INFN-LNF) for the LARES CollaborationI.Ciufolini (PI), Università di Lecce and INFN-Lecce
A. Boni, C. Cantone, S. Dell’Agnello, G. Delle Monache, M. Franceschi, M. Garattini, N. Intaglietta, C. Lops, M.Martini, M.Maiello, C.ProsperiLaboratori Nazionali di Frascati dell’INFN, Frascati, ITALY
G. Bellettini, R.Tauraso, University of Rome Tor Vergata, ITALY S. Berardi, C. Cerruti, F, Graziani, P. Ialongo, A. Lucantoni, A.Paolozzi, I. Peroni, C. Paris, G. Sindoni, C. Vendittozzi
University of Rome Sapienza, ITALYR. March, CNR-IAC, Rome, ITALY
D. G. Currie, University of Maryland at College Park, MD, USAD. Arnold, NASA-GSFC, Greenbelt, MD, USA
E.C.Pavlis, University of Maryland in Baltimore County, USAR. Matzner, University of Texas at Austin, Austin, TX, USA
D. P. Rubincam, NASA-GSFC, Greenbelt, MD, USAV. J. Slabinski, US Naval Observatory, Washington DC, USA
LNF Spring School, May 2008
C. Lops, INFN-LNFLNF Spring School May 08 2
Outline
• Science with Satellite Laser Ranging (SLR)
• LAGEOS physics
• The LARES, the LAser RElativity Satellite– space mission approved by ASI/ESA and experiment approved
by INFN
• The LNF SLR Characterization Facility (SCF)
• Testing new physics
• Outlook
C. Lops, INFN-LNFLNF Spring School May 08 3
LAGEOS: the LAser GEOdynamics SatellitesLAGEOS I (1976; NASA)LAGEOS II (1992; NASA - ASI)
∅= 60 cm
M=400 Kg
N=426 CCRs
Time of flight, atmosphericcorrections
Normal reflection
Retro-reflection
Cube corner retro-reflectors (CCRs)
SLR
C. Lops, INFN-LNFLNF Spring School May 08 4
The SLR Constellation in NEOsAltitudes from few hundred km (LEOs) to~20K Km (GNSS), 35K Km (GEO)
Two very important observables- Geocenter of ITRF- Scale of length of ITRF
are defined uniquely by LAGEOS I & II
C. Lops, INFN-LNFLNF Spring School May 08 5
High-accuracy General Relativity (GR) tests• Of course direct observation of Gravitational Waves is “the”
most important dynamical test of GR• Main theoretical goal: quantum theory of Gravity and
Unification of the 4 interactions. GR is a classic theory• Main experimental goal: where does GR fail ?
– Frame dragging (LAGEOS, GP-B, LAGEOS+LARES)– At what accuracy ? For example, for frame-dragging:
• LAGEOS: 10%• GP-B: 300% (April 14, 2007), now 30%, final results in June 08• LARES: new mission, aims to 1%. Is 1% enough ?
– Other tests:• Space-time curvature (Cassini, PPN γ)• Geodetic/De Sitter precession (Lunar Laser Ranging, PPN β)• Redshift/clock dilation (GP-A, VIKINGS/Shapiro time delay)
• New theories: see slide # 13
Measurement of “frame-dragging” w/LAGEOS
• Raw observed node residuals combined
• Raw residuals with six periodic signals removed, estimated rate is 47.9 mas/yr
• GR-predicted residuals, rate: 48.2 mas/yr
•• Raw observed node Raw observed node residuals combinedresiduals combined
•• Raw residuals with Raw residuals with six periodic signals six periodic signals removed, estimated removed, estimated rate is 47.9 rate is 47.9 masmas/yr/yr
•• GRGR--predicted predicted residuals, rate: residuals, rate: 48.2 48.2 masmas/yr/yr
Earth angular momentum drags space-time around it. The node of LAGEOS satellites(a~12300 Km) is dragged by ~2 m/yr
EIGEN-GRACE02S 2004 data by GFZ1993-2003 LAGEOS I and LAGEOS II data
2/3232 )1(2
eacGJTL
−=Ω −&
Oct. 2004
I.Ciufolini, E. C. Pavlis
C. Lops, INFN-LNFLNF Spring School May 08 7
LAGEOS+LARES vs Gravity Probe B-LAGEOS I, LAGEOS II and LARES:dragging of angular momentum wrt ILRS stations. Passive satellites.LARES is an approved ASI mission and will be launched with the ESA rocket VEGA and is an approved INFN experiment
Gravity Probe B(NASA mission ended in 2006):
dragging of drag-free gyroscope inside very high-tech spacecraft wrt distant guide star IM Pegasi
Cost: few M€ Official cost: 760 M$
C. Lops, INFN-LNFLNF Spring School May 08 8
Critical experimental issues
• Non Gravitational Perturbations(NGP): asymmetric thermal thrustsdue to Solar constant and Earth IR– 2-3% of error on frame dragging
• Velocity aberration. Relative station-satellite velocity requires non-zero expensive CCR dihedral angle offsets w/0.5 arcsec accuracy
• Design to control thermal perturbations on optical performance
• Characterize “as-built” thermal and optical performance at the INFN dedicated facility
Rubincam/Yarkovsky effect
For LARES: θ ~ 2 v/c cosφ ~ 40 mrad ⇒ ~50 m
C. Lops, INFN-LNFLNF Spring School May 08 9
LARES design
Single piece of W-alloy
Ø ~ 39 cm92 CCRs
Equatorialview
MLARES (102 Kg)
Thermal NGPs proportional to satellite Area/MassMLARES ~ MLAGEOS ~ 400 Kg
M/SLARES/M/SLAGEOS ~ 2.7
Work by Scuola Ingegneria Aerospaziale, Rome “Sapienza”
M/SLARES/M/SLAGEOS
C. Lops, INFN-LNFLNF Spring School May 08 10
Optical table, FFDP circuit
The INFN-LNF SLR Characterization Facility (SCF)Thermal and laser tests never perfomed before in space conditions
C. Lops, INFN-LNFLNF Spring School May 08 11
Measured & simulated optical Far Field Diffraction Pattern (FFDP)
Simulated with CodeV Measured @ LNF
Good agreement
Scale is ± 50 μrad
NASA-GSFC proto has dihedral angle
offset = 0.0±0.5 arcsec
C. Lops, INFN-LNFLNF Spring School May 08 12
Thermal SCF-Test and simulation (tough job)
SCF work led byG. O. Delle Monache
T from IR camera τCCR drives NGPsτCCR never measuredτCCR predictions have 300% “error”
Our measurement:σ(τCCR)/ τCCR ~ 10%,which makes thermal NGPs negligible for LAGEOS & LARES
C. Lops, INFN-LNFLNF Spring School May 08 13
LARES limit by I. Ciufolini
Limits on non-newtonian gravity using the perigee
Current limits on additional Yukawa potential:α × (Newt-gravity) × e-r/λ
Expected limit on α set by theLARES mission at an orbit radius
of about 8000 Km.
For a clean perigee measurement1) accurate measurement of
thermal perturbations2) high value of Mass/Area
C. Lops, INFN-LNFLNF Spring School May 08 14
Conclusions
• SLR: the most precise AND cost-effective way to probe gravity in Near Earth Orbits
(Millimeters) .AND. (0.1 M€ to M€)• Not just physics
– Space geodesy– GALILEO has SLR on all satellites
• Three main contributions to science error budget– SLR measurements, Earth grav. models, thermal perturbations– The INFN SCF fills the void of non-existent of space characterization
of SLR• With SLR/LLR we love to test:
– General Relativity– Yukawa deviations from 1/r2, Gravity with Torsion (in progress)
C. Lops, INFN-LNFLNF Spring School May 08 15
Thank you
C. Lops, INFN-LNFLNF Spring School May 08 16
The INFN-LNF SLR Characterization Facility (SCF)Thermal and laser tests never perfomed before in space conditions
C. Lops, INFN-LNFLNF Spring School May 08 17
Science with Satellite Laser Ranging
• Consolidated ToF to measure positions in space with passive, long-lasting targets– Apollo LLR: oldest physics experiment in space with a man-made payload– LAGEOS orbit lifetime is O(1) million years
• SLR is the most (cost-effective).AND.(precise) orbitography– Laser interferometry in space more precise but much more expensive
• Millimeter level precision of SLR is excellent for– Precision tests of Gravity (GR, Unified Theories)– Space Geodesy (ITRF/ICRF)– Global Navigation Satellite System (GALILEO, GPS-3)
ITRF = International Terrestrial/Celestial Reference Frame
C. Lops, INFN-LNFLNF Spring School May 08 18
Other manifestations of frame dragging
SPIN
Spin-time delay and gravitational lensing: can be observable on large scale structures (I. Ciufolini)
Gravitomagnetic clock effects near spinning astrophysical objects
C. Lops, INFN-LNFLNF Spring School May 08 19
Satellite Laser Ranging (SLR)Lunar Laser Ranging (LLR)
• The Moon as a test mass (1969+, Alley, Bender, Currie, Faller …)
• LAGEOS: “cannon-ball”, point-like test-masses covered with laser retro-reflectors (raw orbit accuracy < 1 cm)
LAGEOS:h ~ 6000 KmAPOLLO 11, 14,15
C. Lops, INFN-LNFLNF Spring School May 08 20
LARES and GP-B: main goals & differences
• LARES+LAGEOS: test the gravitomagnetic field at the 1% level. Samegoal as GP-B. LARES costs “a few millions” of euros.
• LAGEOS-only error is now 10%
• GP-B: ~300% error at in April 07 at APS– Web site declares they are now at ~30% level. Final result in June 08– Official cost = 760 M US$; approval in 1964, launch in 2004
• They are based on two DIFFERENT equations for the effect of the gravitomagnetic field, this difference could have profound implications in some gravitational theories embedding GR (for example Gravity withTorsion)
• LARES data analysis may be repeatable by any laboratory. LARES measurements will improve with time, because of longer periods of observations and better modeling of the physical orbital perturbations
C. Lops, INFN-LNFLNF Spring School May 08 21
LARES according to ASI
The ASI President wrote about LARES on Sep. 12, 2007, on an italian newspaper, Corsera
Ciufolini on NATURE, INFN, VEGA, Matera Laser Ranging Observatory, “a few Millions”
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